Organic Ferrimagnetic Material Vanadium Tetracyanoethylene for Non-reciprocal Microwave Applications

Na Zhu, Andrew Franson, S. Kurfman, M. Chilcote, D. Candido, Katherine E. Nygren, M. Flatté, K. Buchanan, E. Johnston-Halperin, H. Tang
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引用次数: 3

Abstract

Vanadium tetracyanoethylene ($V$(TCNE)2) is a new organic ferrimagnetic material known for its ultra low Gilbert damping. Magnetic resonators based on this material demonstrate high quality factors exceeding 7,000 at ambient conditions, rivaling those of inorganic magnetic materials such as Yttrium Iron Garnet (YIG). $V$(TCNE)2 is of particular interest for non-reciprocal device applications thanks to its micro-patterning capabilities. Here we provide a review of the magnetic and microwave properties of $V$(TCNE)2 and discuss its potential applications in microwave circulators. Using a generic multimode coupling model, we describe $V$(TCNE)2-based superconducting circulator and assess its optimal performance in terms of isolation, insertion loss and circulation bandwidth. High isolation (> 59 dB), extremely low insertion loss (< 0.03 dB), and flexible bandwidth control can be potentially realized. By engineering the V(TCNE)2 structures, the devices can operate in both weak and strong coupling regimes, realizing various circulation bandwidths from sub-megahertz to hundreds of megahertz. Especially, the narrow-band circulation could serve as a filter function and benefit noise-sensitive quantum microwave measurements.
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非互易微波应用的有机铁磁材料四氰乙烯钒
四氰乙烯钒($V$(TCNE)2)是一种新型有机铁磁材料,以其超低吉尔伯特阻尼而闻名。基于该材料的磁谐振器在环境条件下显示出超过7,000的高质量因数,可与无机磁性材料(如钇铁石榴石(YIG))相媲美。$V$(TCNE)2是特别感兴趣的非互易器件应用,由于其微模式的能力。本文综述了$V$(TCNE)2的磁性和微波特性,并讨论了其在微波循环器中的潜在应用。利用通用的多模耦合模型,我们描述了基于$V$(TCNE)2的超导环行器,并从隔离、插入损耗和循环带宽方面评估了其最佳性能。高隔离度(> 59 dB),极低的插入损耗(< 0.03 dB)和灵活的带宽控制可以潜在地实现。通过设计V(TCNE)2结构,器件可以在弱耦合和强耦合状态下工作,实现从亚兆赫到数百兆赫的各种循环带宽。特别是,窄带环流可以作为滤波功能,有利于噪声敏感的量子微波测量。
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